This invention generally relates to a reduced-wear synthetic fiber rope for various marine applications, particularly, a rope having a low-friction strand.
Synthetic fiber ropes are used to carry tensile loads in various applications, such as working and lifting, towing, buoy mooring, tug and salvage operations, ship and barge mooring, commercial fishing, etc. The useful life of such ropes is limited due to wear of the individual fibers, which may be caused, to some extent, by the friction of the fibers rubbing against each other. The fibers rub against each other, for example, when a rope passes over a sheave or as the rope moves from a slack configuration to a configuration in which it carries a tensile load.
Prior attempts to alleviate friction and wear in the rope have included intertwining low-friction fibers with the high-friction fibers of the rope and adding lubricant or lubricating fibers to the rope. Such solutions may fail to achieve the desired reduction in friction and rope wear and may present independent shortcomings, for example, reduced rope performance (e.g., reduced friction in winching, splicing of the rope).
As such, a need exists for a rope with, for example, a longer useful life, improved performance, etc., compared to previous ropes. Such a rope may be subjected to less wear due to reduced friction between the rope's fibers while achieving acceptable performance in applications in which outer surface friction may be desired (e.g., winching, splicing, etc.).
In one independent aspect, a rope may generally include a plurality of primary strands each including a plurality of fibers formed of a high-friction material, the plurality of primary strands defining an outer surface and a longitudinal center passageway of the rope; and a non-load bearing secondary strand having a strand outer surface and disposed within the longitudinal center passageway of the rope, the secondary strand including, at least on the strand outer surface, a plurality of structurally stable fibers formed of a non-flowable, low-friction material.
In another independent aspect, a rope may generally include a plurality of outer strands together defining an outermost surface of the rope and a longitudinally-extending center passageway of the rope, each of the plurality of outer strands including a plurality of fibers formed of a high-friction material, the high-friction material defining a first coefficient of friction with itself; and a core strand disposed within the longitudinally-extending center passageway of the rope and separated from the outermost surface of the rope by at least one of the plurality of outer strands at all positions along a length and about a circumference of the rope, the core strand including a plurality of structurally stable fibers formed of a non-flowable, low-friction material, the non-flowable low-friction material defining a second coefficient of friction with the high-friction material, the second coefficient of friction being less than the first coefficient of friction.
In yet another independent aspect, a rope may generally include twelve outer strands together defining a longitudinally-extending center passageway of the rope, the twelve outer strands being braided in a single braid pattern, each of the twelve outer strands including twelve sub-strands braided in a single braid pattern, each of the sub-strands including a plurality of synthetic fibers; and a core strand disposed in the longitudinally-extending center passageway over the length of the rope, the core strand including a plurality of fibers.
In a further independent aspect, a method of constructing a rope may generally include providing a non-load bearing secondary strand having a strand outer surface, the secondary strand including, at least on the strand outer surface, a plurality of structurally stable fibers formed of a non-flowable, low-friction material; and surrounding the secondary strand with a plurality of primary strands each including a plurality of fibers formed of a high-friction material, the plurality of primary strands defining an outer surface and a longitudinal center passageway of the rope, the secondary strand being disposed within the passageway.
Independent features and independent advantages of the invention will become apparent to those skilled in the art upon review of the detailed description, drawings and claims.
Before any independent embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other independent embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting. Use of “including” and “comprising” and variations thereof as used herein is meant to encompass the items listed thereafter and equivalents thereof as well as additional items. Use of “consisting of” and variations thereof as used herein is meant to encompass only the items listed thereafter and equivalents thereof.
Referring to
In addition, because the illustrated low-friction material is separate from the outer strands 12, the low-friction material can be removed from the rope 10, as necessary. For example, the low-friction material can be removed at an end section of the rope 10 for splicing, for termination, etc. In such instances, the section of the rope 10 with the low-friction material removed will perform like a rope without any low-friction material.
It should be understood that the terms “high” and “low” are relative terms. For example, in the illustrated constructions, the outer strands 12 and fibers 16 have a higher coefficient of friction than the core strand 14 and fibers 22 which, in turn, have a lower coefficient of friction than the outer strands 12/fibers 16. Similarly, the outer strands 12 and fibers 16 may have a higher strength than the core strand 14 and fibers 22 which, in turn, have a lower strength than the outer strands 12/fibers 16.
The illustrated rope 10 includes a plurality of primary, load bearing strands 12 surrounding at least one auxiliary, non-load bearing strand 14. The illustrated center strand 14 is a low-friction strand (relative to the illustrated outer strands 12) to reduce the friction at the center of the rope 10, which is where most of the friction occurs. As such, the fibers of the rope 10 are subjected to relatively little wear as they rub against each other, resulting in, for example, an increased useful life compared to previous ropes.
Turning to
The fibers 16 may comprise materials such as, without limitation, a recrystallized high modulus polyethylene (for example, Plasma®), a liquid crystal polyester (LCP; for example, Vectran® available from Kuraray Co., Japan), a gel-spun polyethylene (for example, Spectra® available from Honeywell International, Inc., New Jersey, U.S.A.), a para-aramid (for example, Kevler® available from DuPont, Delaware, U.S.A. or Twaron® available from Teijin Aramid B.V., The Netherlands), a para-aramid copolymer (for example, Technora® available from Teijin Aramid B.V.), a polyamide (nylon), a polyester, or the like or combinations thereof. The fibers 16 may have a polyurethane finish, although other finishes may alternatively be used.
In some constructions, one or more of the outer strands 12 may include composite strands formed of more than one material, such as more than one of the exemplary materials identified above. In some other constructions (e.g., in which the coefficient of friction of the rope surface is of less importance) and for other aspects of the invention, one or more of the outer strands 12 may include composite strands formed of both high- and low-friction materials. For example, the rope 10 may include a structure similar to that described in U.S. Pat. No. 6,945,153, entitled “Rope for Heavy Lifting Applications”, the disclosure of which is also hereby incorporated by reference.
The plurality of outer strands 12 may be braided with one another. For example, the outer strands 12 may be braided in a “12×12” pattern like ropes provided by Cortland Cable of Cortland, N.Y. That is, there may be twelve outer strands 12 braided in a single braid pattern, and each of the twelve outer strands 12 may in turn include twelve sub-strands braided in a single braid pattern. The sub-strands may in turn include a plurality of synthetic fibers 16; each strand 12 may be braided with a center sub-strand formed of a low-friction material (e.g., fibers 22) in a manner similar to the construction of the illustrated rope 10. Similarly, the plurality of outer strands 12 may define a rope structure as described in U.S. Pat. No. 5,901,632, entitled “Rope Construction”, the disclosure of which is hereby incorporated by reference.
The rope 10 and/or the plurality of outer strands 12 may alternatively be braided using other patterns (e.g., 12×3, 12×8, etc.) in which the rope or strand is braided with its core separated from its outer surface. In any case, the plurality of outer strands 12 define the outer surface 18 of the rope 10 and an inner longitudinally-extending passageway 20 in which the center strand 14 is disposed.
Turning to
The fibers 22 may comprise, for example, without limitation, ultra-high molecular weight polyethylene (UHMWPE)-based materials such as low-friction UHMWPE (for example, Dyneema® UHMWPE available from DSM N.V., The Netherlands, Spectra® 900 and Spectra® 1000 available from Honeywell International, Inc., or Endumax® available from Teijin Aramid B.V.), fluoropolymer-based materials such as expanded polytetrafluoroethylene (ePTFE; comprising non-flowable, stable, and solid fibers; for example, Omnibend® available from W. L. Gore & Associates, Inc., Delaware, U.S.A.), modified polytetrafluoroethylene, fluorinated ethylenepropylene (FEP), ethylene-chlorotrifluoroethylene (ECTFE), ethylene-tetrafluoroethylene (ETFE), a perfluoroalkoxy polymer (PFA), or the like or combinations thereof.
In one exemplary rope 10, the fibers 22 of the center strand 14 may comprise a fluoropolymer-based material (e.g., ePTFE), and the fibers 16 of the outer strands 12 may comprise a para-aramid copolymer (for example, Technora®). In another example, the fibers 22 may comprise a fluoropolymer-based material (e.g., ePTFE), and the fibers 16 may comprise UHMWPE.
The material of the fibers 22 is structurally stable and non-flowable, meaning that it stays positioned in the passageway 20 and does not flow, creep or get squeezed out between the outer strands 12 to the outside of the rope 10. The fibers 22 may be braided, twisted, etc.
The fibers 22 and the center strand 14 are disposed in the passageway 20 defined by the outer strands 12 over the entire length of the rope 10. Furthermore, the center strand 14 is separated from the outer surface 18 by at least one of the outer strands 12 at all points along the entire length and about the entire circumference of the rope 10. As such, the center strand 14 reduces the friction at the center of the rope 10, and the fibers 16, 22 are subjected to relatively little wear as they rub against each other.
The diameter of the center strand 14 (or the largest cross-sectional dimension if the strands 12 are compressed against one another) is such that the center strand 14 does not adversely affect the performance of the outer stands 12 and the rope 10 (e.g., does not interfere with the load-carrying capabilities of the outer strands 12). As a practical example, a center strand 14 that is at most one-third of the diameter of each of the outer strands 12 (or the largest cross-sectional dimension) will generally not affect the performance or the outer diameter of a given rope 10. However, it should be understood that the center strand 14 may be smaller or larger (even as large as or larger than the outer strands 12).
In some constructions, the center strand 14 may be formed of a low-friction, high-strength material. In some constructions, the center strand 14 may include a composite strand formed of more than one material, such as more than one of the exemplary materials identified above. In some constructions (not shown), the rope 10 may include more than one center strand 14.
In some other constructions (see
The core element 24 may be braided. To surround the core element 24, the low-friction material (e.g., fibers 22) may, for example, form a braided jacket or be twisted around the core element 24 to define the low-friction strand 14a.
The core element 24 may comprise, for example, without limitation, a multi-filament polyester (available from Kuraray, Co., Japan; Teijin Limited, Japan; or Unifi, Inc., North Carolina, U.S.A.), a para-aramid copolymer (for example, Technora® available from Teijin Aramid B.V.), a liquid crystal polyester (LCP; for example, Vectran® available from Kuraray Co., Japan), a polyamide, a polyester, or the like or combinations thereof.
Such a hybrid center strand construction may be used in larger ropes (e.g., having a diameter of 3⅝″ or greater or a circumference of 80 mm or greater) in which a larger passageway 20 can be formed. Relatively-expensive low-friction material can be used with less expensive material of the core element 24 to form a larger center strand 14a to occupy the larger passageway 20.
When the rope 10 is used, all strands 12, 14 move relative to each other. As the rope 10 is used and tension added (see
From the above description, it should be apparent that the present invention provides a rope that may include a structurally stable, non-flowable, low-friction center strand to reduce the friction at the center of the rope while maintaining the coefficient of friction of the rope surface. As such, the fibers of the rope may be subjected to reduced wear as they rub against each other, resulting in increased useful life and improved performance compared to previous ropes.
One or more independent features and independent advantages of the invention may be set forth in the following claims:
This application claims the benefit of prior-filed, U.S. Provisional Application No. 61/752,195, filed Jan. 14, 2013, the entire contents of which is hereby incorporated by reference.
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